Decellularized biologically-engineered tubular grafts

ABSTRACT

This disclosure describes decellularized, biologically-engineered tubular grafts and methods of making and using such decellularized, biologically-engineered tubular grafts.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of, and claims the benefit of priority under 35 U.S.C. § 120 to, U.S. application Ser. No. 14/633,268 filed Feb. 27, 2015, which is a divisional of, and claims the benefit of priority under 35 U.S.C. § 121 to, U.S. application Ser. No. 13/771,676 filed Feb. 20, 2013, which claims the benefit of priority under 35 U.S.C. § 119(e) to U.S. Application No. 61/691,394 filed Aug. 21, 2012.

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was made with government support under HL083880, HL071538, and HL107572 awarded by National Institutes of Health Heart, Lung and Blood Institute (NHLBI). The government has certain rights in the invention.

TECHNICAL FIELD

This disclosure generally relates to decellularized tubular grafts and methods of making and using such decellularized tubular grafts.

BACKGROUND

Cardiovascular disease is the leading cause of mortality in the world: approximately one million surgical procedures are performed annually in the US alone. Vascular grafts made from synthetic polyesters have shown success in replacement of large diameter vessels such as the thoracic and abdominal aortas, aortic arch vessels, as well as the iliac and femoral arteries. However, they have generally proven inadequate as small-diameter (<6 mm) arterial grafts. This is primarily a result of acute graft thrombogenicity, anastomotic intimal hyperplasia, aneurysm formation and infection. Autologous arteries and veins remain the standard of care. However, a significant fraction of patients do not have a suitable vessel that can be harvested as a replacement and donor site morbidity occurs. Therefore, tissue engineering provides a viable alternative to create arterial grafts that can maintain vascular function comparable to native vessels.

SUMMARY

This disclosure describes decellularized tubular grafts and methods of making and using such decellularized tubular grafts.

In one aspect, a decellularized, biologically-engineered tubular graft is provided. Such a biologically-engineered tubular graft includes cell-produced extracellular matrix, wherein fibers within the biologically-engineered tubular graft are aligned circumferentially. Such a decellularized, biologically-engineered tubular graft exhibits greater tensile stiffness in the circumferential direction than in the longitudinal direction and exhibits a burst pressure that statistically significantly exceeds a physiological pressure. In another aspect, a biologically-engineered tubular valve is provided that includes a decellularized, biologically-engineered tubular graft.

The cell-produced extracellular matrix can originate from a composition that includes matrix-producing cells, fibrinogen or a fibrinogen-like material, and thrombin. In some embodiments, the matrix-producing cells are fibroblasts such as human dermal fibroblasts.

In some embodiments, the tubular graft exhibits a burst pressure of at least 2500 mm Hg, at least 3000 mm Hg, at least 3500 mm Hg, or at least 4000 mm Hg. In some embodiments, the tubular graft has an average diameter of about 0.5 mm to about 6 mm, about 5 mm to about 12 mm, about 10 mm to about 20 mm, or about 18 mm to about 24 mm. Representative tubular grafts include, without limitation, a vascular graft (e.g., an arterial graft or a venous graft), a urethra graft, a fallopian tube graft, a Vas deferens graft, or a Eustachian tube graft.

In another aspect, a method of making the decellularized, biologically-engineered tubular graft described herein is provided. Such a method typically includes combining fibrinogen or fibrinogen-like material, thrombin, and matrix-producing cells to produce a cell-seeded fibrin gel; molding the cell-seeded fibrin gel into the shape of a hollow tube; manipulating, mechanically, the tube in the presence of culture medium to produce a biologically-engineered tubular graft; and decellularizing the biologically-engineered tubular graft. In some embodiments, such a method further can include anchoring one end of the decellularized, biologically-engineered tubular graft at two positions, three positions, or four positions to shape the decellularized, biologically-engineered tubular graft into a bi-, tri- or quad-leaflet valve, respectively. In still another aspect, a biologically-engineered valve made by such a method is provided.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the methods and compositions of matter belong. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the methods and compositions of matter, suitable methods and materials are described below. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic showing a representative method of using a decellularized, biologically-engineered tubular graft to make a biologically-engineered valve.

FIG. 2 is a schematic showing a representative method of using a decellularized, biologically-engineered tubular graft to make a biologically-engineered valve. The anchor points in FIG. 2 are created by suturing one tube within another.

FIG. 3 is a schematic, including photographs, showing a representative method of using a decellularized biologically-engineered tubular graft to make a biologically-engineered valve. A frame in FIG. 3 provides the anchor points.

DETAILED DESCRIPTION

This disclosure describes a method of making the decellularized, biologically-engineered tubular graft and also describes the subsequently produced decellularized, biologically-engineered tubular graft. Initially, fibrinogen or fibrinogen-like material, thrombin, and matrix-producing cells are combined, and the resulting cell-seeded gel composition is molded into the shape of a hollow tube. The fibrin-based gel is remodeled into an extracellular matrix by the matrix-producing cells, which retains the tubular shape of the original mold.

Fibrinogen is a well known soluble glycoprotein naturally found in blood, and is converted to fibrin by the action of thrombin, a serine protease, during blood coagulation. As used herein, fibrinogen-like material refers to proteins, natural or synthetic, that have similar characteristics to those of fibrinogen and, which, as described herein, can be converted into a fibrin-like material and, eventually, into an extracellular matrix material. One example of a fibrinogen-like material is PEGylated-fibrinogen (see, for example, Suggs et al., 1998, J. Biomater. Sci. Polym. Ed., 9:653-66).

As used herein, “matrix-producing cells” are those cells that have the capability of converting fibrinogen or a fibrinogen-like material, in the presence of thrombin, into extracellular matrix. As described herein, fibroblast cells are very efficient at producing extracellular matrix material as are smooth muscle cells. Fibroblasts are well known and can be human fibroblasts, primate fibroblasts, rodent fibroblasts, or any other type of mammalian fibroblasts. Fibroblasts can be obtained from, for example, any number of different anatomical tissues (e.g., dermis, lung, connective tissue, kidney, etc.), commercial sources (e.g., Millipore, Cell Applications, StemGent, etc.), and/or biological depositories (e.g., American Type Culture Collection (ATCC)). The same is true for smooth muscle cells. The matrix-producing cells can be combined with the fibrinogen or fibrinogen-like material, and the thrombin and then molded, or the matrix-producing cells can be seeded into a composition that includes fibrinogen or fibrinogen-like material and thrombin and that has been molded into a tubular shape.

While matrix-producing cells at any passage beyond three passages (e.g., four, five, six, seven, eight, nine, or ten passages) can be used in combination with the fibrinogen or fibrinogen-like material, it is preferred that the matrix-producing cells that are used have been grown for between three passages and seven passages. For example, fibroblasts can be grown for between three passages and six passages, for between four passages and six passages, for between four passages and seven passages, or for between five passages and seven passages. In addition, the number of matrix-producing cells used initially in a tubular graft as described herein can be, for example, from about 10² cells to about 10¹² cells (e.g., about 10³ cells to about 10¹⁰ cells, about 10⁴ cells to about 10⁹ cells, 10⁵ cells to about 10⁸ cells, or about 10⁶ cells to about 10⁷ cells).

Hydrogels are well known in the art and generally refer to hydrophilic polymeric chains that can contain natural or synthetic polymers. One or more hydrogels optionally can be included in the composition. Any number of suitable hydrogels can be used, if desired, to support and mold the cell-seeded fibrin gel (e.g., comprising fibrinogen or fibrinogen-like material and the matrix-producing cells) as necessary. Representative hydrogels include, for example, agarose, methylcellulose, hyaluronan, and combinations thereof. If present, the amount of hydrogel used in a composition described herein can range from about 10% to about 80% (e.g., about 20% to about 70%, about 30% to about 60%, about 40% to about 50%, or about 50%). The presence of and the actual amount of one or more hydrogels will depend upon the desired features of the cell-seeded fibrin gel or the subsequently produced biologically-engineered tubular graft (e.g., softness or hardness, flexibility, absorbency).

The cell-seeded gel can be molded around, for example, a mandrel, in order to obtain a hollow tube. Mandrels of different sizes can be used depending upon the desired size of the hollow tube. For example, a tubular graft as described herein can have a diameter of about 0.5 mm up to a diameter of about 24 mm (e.g., about 1 mm, about 2 mm, about 5 mm, about 10 mm, about 15 mm, about 20 mm, about 21 mm, about 22 mm, about 23 mm, or about 24 mm in diameter; about 0.5 mm to about 6 mm, about 5 mm to about 12 mm, about 10 mm to about 18 mm, about 15 mm to about 21 mm, about 20 mm to about 24 mm, or about 18 mm to about 24 mm in diameter). In some embodiments, the diameter of the tubular graft can be an appropriate size for use as a vascular graft (e.g., an arterial or venous graft, or arterio-venous fistula). For example and without limitation, the diameter of the tubular graft can be an appropriate size for use as a graft for a urethra, a fallopian tube, a Vas deferens, or a Eustachian tube. In addition, the larger diameter tubular grafts can be used to encircle or ensheath a structure such as, without limitation, a heart valve construct. The length of the tubular graft will be any length that is appropriate or necessary to graft. For example, a tubular graft as described herein can be from about 3.0 mm up to about 20 cm in length (e.g., about 3.0 mm to about 10.0 mm, about 5.0 mm to about 20.0 mm, about 25.0 mm to about 5.0 cm, about 50.0 mm to about 10 cm, about 10 cm to about 15 cm, about 10 cm to about 20 cm, about 15 cm to about 20 cm in length).

This combination of materials, over time, is converted by the cells into an extracellular matrix (referred to herein as a “cell-produced extracellular matrix”), typically in a controlled laboratory setting. While the tubular graft is undergoing this transformation from the cell-seeded gel into the cell-produced extracellular matrix, the tubular graft can be mechanically manipulated (or “conditioned”) in any number of fashions. Mechanical manipulations include, for example, static culture on the mandrel, which, for a non-adhesive mandrel, leads to circumferential alignment as the cells compact the gel, causing the axial length to shorten, and circumferential stretching or distension while providing for axial shortening to maintain the circumferential alignment. Generally, such stretching or distortion is cyclic or periodic. See, for example, Syedain et al., 2011, Biomaterials, 32:714-22. Simply by way of example, mechanical manipulations of the cell-seeded gel as it is remodeled into a cell-produced extracellular matrix can be performed using flow-stretch or pulsed flow-stretch methods in any number of bioreactors.

Such mechanical manipulation typically is done in the presence of culture medium in order to maintain cell viability during the conversion process. The culture medium is the same medium usually used to culture cells such as fibroblasts, and includes components such as, without limitation, serum, amino acids, salts (e.g., calcium chloride, potassium chloride, magnesium sulfate, sodium chloride, and/or monosodium phosphate), glucose, and vitamins (e.g., folic acid, nicotinamide, riboflavin, and/or B12).

The biologically-engineered tubular graft then can be decellularized. Decellularization can take place using any number of different methods. See, for example, WO 2007/025233, WO 2010/120539, Ott et al. (2008, Nat. Med., 14:213-21), Baptista et al. (2009, Conf. Proc. IEEE Eng. Med. Biol. Soc., 2009:6526-9) or Crapo et al. (2011, Biomaterials, 32:3233-43).

The resulting decellularized, biologically-engineered tubular graft exhibits a number of novel features. For example, the fibers are aligned circumferentially around the tubular graft, which results in a decellularized, biologically-engineered tubular graft that exhibits greater tensile stiffness in the circumferential direction than in the longitudinal direction. In addition, the decellularized, biologically-engineered tubular graft described herein exhibits a burst pressure that exceeds, and, in many cases, statistically significantly exceeds, the pressure to which vasculature is normally or typically exposed (i.e., physiological pressure). For example, a decellularized, biologically-engineered tubular graft described herein can withstand a pressure of at least 2000 mm Hg, at least 2500 mm Hg, at least 3000 mm Hg, at least 3500 mm Hg, at least 4000 mm Hg, or greater than 4000 mm Hg, without bursting. In other words, a decellularized, biologically-engineered tubular graft described herein can exhibit a burst pressure of at least 2000 mm Hg, at least 2500 mm Hg, at least 3000 mm Hg, at least 3500 mm Hg, at least 4000 mm Hg, or greater than 4000 mm Hg. Moreover, the cell-produced extracellular matrix is conducive to recellularization (i.e., cells, including endothelial cells populating the luminal surface and tissue cells penetrating and repopulating the interior cavity) both in culture in the laboratory and endogenously following implantation or engraftment.

As indicated herein, a decellularized, biologically-engineered tubular graft can be implanted or engrafted directly following decellularization. Alternatively, a decellularized, biologically-engineered tubular graft can be used to form a tissue-engineered valve before being implanted or engrafted. For example, one end of a decellularized, biologically-engineered tubular graft as described herein can be anchored at two points (for a bi-leaflet valve), three points (for a tri-leaflet valve) or four points (for a quad-leaflet valve) using a suture, an adhesive, or other suitable bonding method.

The schematic shown in FIG. 1 shows a structure in which two, three and four anchoring points are created. This leads to the formation of a structure, which, under fluid back-pressure, causes the tube to collapse and create a valvular action that is very similar to a bi-, tri- or quad-leaflet valve. Alternatively, FIG. 2 is a schematic showing an embodiment in which one tube is sutured to a tube placed over the first tube. As shown in FIG. 2, suture lines are created that define, in the example shown, three ‘U’ shapes around the circumference of the tube. This leads to the formation of a structure as described above that, under fluid back-pressure, causes the inner tube to collapse and create a valvular action that is very similar to, in the example shown, a tri-leaflet valve.

In addition to the embodiment shown in FIG. 2, three points of anchorage can be made using a material that is placed inside (e.g., a stent) or outside (e.g., a frame) the tubular graft, which can be made of a rigid material for a frame (e.g. titanium) or a flexible material for a stent (e.g. braided Nitinol wire mesh). FIG. 3 shows an embodiment in which a tissue tube is placed on the outside of a rigid frame containing three struts as anchoring points.

In addition to the anchoring methods described herein, which can be used to make tissue-engineered valves, methods of modifying the biologically-engineered tubular graft also are provided. For example, a biologically-engineered tubular graft can be formed with controlled release agents, or conjugated with biomolecules, or cross-linked, or recellularized.

In accordance with the present invention, there may be employed conventional molecular biology, microbiology, biochemical, and recombinant DNA techniques within the skill of the art. Such techniques are explained fully in the literature. The invention will be further described in the following examples, which do not limit the scope of the methods and compositions of matter described in the claims.

EXAMPLES Example 1—Production and Implantation of Tubular Graft

Engineered grafts (4 mm ID, 2-3 cm long, 0.4 mm thickness) were fabricated from ovine dermal fibroblasts using the pulsed-flow-stretch (PFS) bioreactor and decellularized using sequential treatment with SDS, Triton-X, and DNase, which had little effect on graft properties. The total graft culture time was 7 weeks. The burst pressure of the decellularized grafts exceeded 4000 mm Hg and had the same compliance as the ovine femoral artery. No cells were visible with histological staining and DNA content was less than 10% of the untreated grafts. The decellularized grafts were implanted interpositionally in the femoral or carotid artery of 4 sheep (n=6) for 8 weeks, in some cases the contralateral position being used for a graft or sham control, where the native artery segment being sutured back into place, and into 2 sheep (n=4) for 24 weeks. Anticoagulation therapy was used for the duration, but no immunosuppression was used.

Example 2—Physiology of Implanted Tubular Grafts

At both 8 and 24 weeks, all grafts were patent and showed no evidence of dilatation or mineralization. Mid-graft lumen diameter was unchanged. Lumen diameter at the ends was 15% smaller for the grafts at 7 weeks based on echocardiography, with a similar trend for the controls, but this was not statistically significant at 24 weeks. A thin neointima was evident near the ends of the grafts. Extensive recellularization occurred, with most cells expressing SMA. Deposition of organized elastin was evident. Endothelialization was complete at the ends of the grafts and partial mid-graft at 8 weeks and complete at 24 weeks. Complementary in vitro studies with a parallel plate flow chamber also indicate excellent shear resistance at physiological shear stresses of pre-seeded blood outgrowth endothelial cells and mesenchymal stem cells. These studies indicate that the completely biological grafts possessing circumferential alignment/tensile anisotropy, can be implanted into the arterial circulation without dilation or mineralization and minor intimal hyperplasia, and with favorable cell seeding, recellularization, and matrix remodeling.

Example 3—A Tissue-Engineered Tubular Valve

A tissue-engineered tubular graft having a lumen diameter of about 15-30 mm was decellularized as described in Example 1. One end of the tube was anchored at three points spaced approximately equally around the circumference of the tube using a suture (as shown schematically in FIG. 1).

FIG. 3 shows an embodiment in which a tissue tube is anchored around a rigid frame. The tissue tube was sleeved over the outside of the frame and stitched along the three posts and around the bottom rim using a prolene suture. Under fluid back-pressure, the tissue tube collapses between the three posts and creates a valvular action similar to a tri-leaflet valve.

It is to be understood that, while the methods and compositions of matter have been described herein in conjunction with a number of different aspects, the foregoing description of the various aspects is intended to illustrate and not limit the scope of the methods and compositions of matter. Other aspects, advantages, and modifications are within the scope of the following claims.

Disclosed are methods and compositions that can be used for, can be used in conjunction with, can be used in preparation for, or are products of the disclosed methods and compositions. These and other materials are disclosed herein, and it is understood that combinations, subsets, interactions, groups, etc. of these methods and compositions are disclosed. That is, while specific reference to each various individual and collective combinations and permutations of these compositions and methods may not be explicitly disclosed, each is specifically contemplated and described herein. For example, if a particular composition of matter or a particular method is disclosed and discussed and a number of compositions or methods are discussed, each and every combination and permutation of the compositions and the methods are specifically contemplated unless specifically indicated to the contrary. Likewise, any subset or combination of these is also specifically contemplated and disclosed. 

What is claimed is:
 1. A decellularized, biologically-engineered graft, made by a method comprising: combining matrix-producing cells, fibrinogen and thrombin to produce a cell-seeded fibrin gel, shaping and conditioning the gel in the presence of culture medium to result in a cell-produced extracellular matrix comprising circumferentially aligned fibers, wherein the conditioning comprises stretching or distending the gel and/or the extracellular matrix, during which and axial length of the gel and/or the extracellular matrix shortens; and decellularizing the extracellular matrix to produce the decellularized, biologically engineered graft.
 2. The decellularized, biologically-engineered graft of claim 1, wherein the number of matrix-producing cells is between about 10² matrix-producing cells and about 10¹² matrix-producing cells.
 3. The decellularized, biologically-engineered graft of claim 1, wherein the matrix-producing cells are fibroblasts.
 4. The decellularized, biologically-engineered graft of claim 3, wherein the fibroblasts are dermal fibroblasts.
 5. The decellularized, biologically-engineered graft of claim 1, wherein shaping comprises molding the cell-seeded fibrin gel into a tube.
 6. The decellularized, biologically-engineered graft of claim 5, wherein the tube is hollow.
 7. The decellularized, biologically-engineered graft of claim 1, wherein the decellularized graft is tubular.
 8. The decellularized, biologically-engineered graft of claim 7, wherein the tubular graft is hollow.
 9. The decellularized, biologically-engineered graft of claim 1, wherein the graft exhibits greater tensile stiffness in the circumferential direction than in the longitudinal direction.
 10. The decellularized, biologically-engineered graft of claim 1, wherein the graft exhibits a burst pressure of at least 2000 mm Hg.
 11. The decellularized, biologically-engineered graft of claim 1, wherein the decellularized graft is a vascular graft.
 12. The decellularized, biologically-engineered graft of claim 11, wherein the decellularized graft is an arterial graft.
 13. The decellularized, biologically-engineered graft of claim 11, wherein the decellularized graft is a venous graft.
 14. The decellularized, biologically-engineered graft of claim 1, wherein the decellularized graft is selected from the group consisting of a urethra graft, a fallopian tube graft, a Vas deferens graft, or a Eustachian tube graft.
 15. The decellularized, biologically-engineered graft of claim 1, wherein the decellularized graft has an average diameter of about 0.5 mm to about 6 mm.
 16. The decellularized, biologically-engineered graft of claim 1, wherein the decellularized graft has an average diameter of about 5 mm to about 12 mm.
 17. The decellularized, biologically-engineered graft of claim 1, wherein the decellularized graft has an average diameter of about 10 mm to about 20 mm.
 18. The decellularized, biologically-engineered graft of claim 1, the method further comprising anchoring one end of the decellularized graft at two or more positions to shape the decellularized graft into a leaflet valve.
 19. The decellularized, biologically-engineered graft of claim 18, wherein the anchoring is at two positions to shape the decellularized graft into a bi-leaflet valve.
 20. The decellularized, biologically-engineered graft of claim 18, wherein the anchoring is at three positions to shape the decellularized graft into a tri-leaflet valve.
 21. The decellularized, biologically-engineered graft of claim 18, wherein the anchoring is at four positions to shape the decellularized graft into a quad-leaflet valve.
 22. The decellularized, biologically-engineered graft of claim 18, wherein the one end of the decellularized graft is anchored at two or more positions to a stent.
 23. A decellularized, biologically-engineered tissue, made by a method comprising: combining fibrinogen or fibrinogen-like material, thrombin, and matrix-producing cells to produce a cell-seeded gel composition; conditioning the gel composition in the presence of culture medium to remodel the composition into a cell-produced extracellular matrix comprising circumferentially aligned fibers, wherein the conditioning comprises stretching or distending the gel composition and/or the extracellular matrix, during which and axial length of the gel composition and/or the extracellular matrix shortens; and decellularizing the extracellular matrix to produce a decellularized tissue. 